lecture 9 - intro. to metam. rocks
TRANSCRIPT
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FUNDAMENTAL CONCEPTS IN METAMORPHIC PETROLOGY
Study of metamorphism deals with the physico-chemical conditions of recrystallization. The study of
metamorphic rocks gives us very important information about 1) the pressure and temperature
conditions of tectonic processes and 2) the nature of fluid flow in the deep crust. Changes in P, T, and
fluid compositions result in reactions among minerals to produce new minerals. Therefore, by studyingmineral assemblages in metamorphic rocks we can deduce the conditions of metamorphism.
I. Types of Metamorphism
1. Contact metamorphism is the result of intrusion of magmas into colder, upper crustal rocks. The
zone of metamorphism is called the contact aureole. The change in metamorphic grade, as expressed in
change in the mineral assemblage, is generally concentric to the intrusion. Contact metamorphism can
be thought of being isobaric at a given crustal level. It involves fairly rapid changes temperature.
(Time interval is 200,000 years.)
Factors influencing nature of a contact aureole:
Size of igneous body. The larger the body, the larger the aureole.
Temperature difference between magma and wall-rocks. The larger the difference, the
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larger the apparent effect of metamorphism.
2. Regional metamorphism
A. Orogenic (most important)
related to formation of orogenic belts
hundreds to thousands km2
T up to 800 C observed
geothermal gradient > normal (30-50C/km)
metamorphism isdynamothermal, meaning it is associated with deformation (get foliated
rocks)
Burial regional metamorphism
result of simple burial
T is normal geothermal gradient (max ~400C)
Ocean floor metamorphism
involves the alteration of the ocean crust by seawater while the crust is still hot
typical minerals include serpentine, chlorite, epidote, zeolites, etc.
3. Hydrothermal metamorphism
mineral reactions are controlled by fluid flow and compositions of fluids
is usually associated with all other types of metamorphism
metasomatism involves the movement of chemicals, such as Si, Cl, Na, metals, by
hydrothermal fluids
4. Fault-zone (cataclastic) metamorphism
involves crushing and grinding by friction during movement along faultsmetamorphism is local in extent
low temperature; high pressure
causes formation offault breccia, or fine-grained, foliated rock calledmylonite
5. Impact (shock) metamorphism
occurs during impact of meteorites and other extraterrestrial objects
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involves very high pressures and temperatures generated by energy of the impact.
involves the formation of high-pressure polymorphs of minerals (e.g. coesite and
stishovite) or loss of internal structure of minerals (e.g. feldspars)
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II. Pressure and Temperature Regimes in the Crust
1. Pressure
Many metamorphic reactions are dehydration or decarbonation reactions. An often made assumption in
metamorphic petrology is that the fluid pressure equals the total pressure on the rock system. However,in the upper few kilometers in the crust where pores in rocks are filled with fluids and the pore spaces
are connected, the fluid pressure in pore-spaces is that exerted by overlying column of the fluid. Thus
thefluid pressure (Pfluid) is hydrostatic. It is given by the weight of the overlying column of the water.
Pfluid = fluidgh
where fluid is the density of the fluid, g is gravitational constant, and h is depth. Because the fluids in
metamorphic rocks are typically not pure H2O, to total
Pfluid =pH2O + PCO2 + ... .
However, at depths >~6 km, fluid pressure becomes equal to the lithostatic pressure:
Pfluid= Plith,
because at the high pressures the fluid cannot keep pore-spaces open anymore as the minerals push
against each other. Lithostatic pressure is given by the weight of the overlying rocks:
Plith = rockgh .
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2. Metamorphic field gradients (metamorphic series)
In a given regional metamorphic terrane, a given prograde metamorphic sequence usually indicates an
increase in both temperature and/or pressure. However, the prograde sequence may not necessarily
represent an originally vertical section through the crust at the time of metamorphism. Therefore, the
apparent P-Tgradient is not indicative of the geothermal gradient that existed in the crust during
metamorphism. However, because the gradient is observed in the field, it is called themetamorphic
field gradient.
A) Hornfels series isobaric contact metamorphism. However, it can occur at higher pressures than
indicated.
B) Buchan series low-P regional metamorphism, usually cause by intrusion of large volume of
magmas into the upper crust.
C) Barrovian series occurs in orogenic terranes by dynamothermal metamorphism.
D) Blueschist (Franciscan) series high-P/low-T series occurs in subduction zone environments.
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P
T
a
b
c
max in P
max in T
III. Metamorphic Pressure-Temperature-Time Paths
Assume that a several km thick section of a sedimentary pile, represented by samples a-c, gets buried
during crustal convergence in an orogen and then gets exposed at the surface:
a
b
c
mantle
The pressure on the rocks increases faster than they get heated up. Therefore, the three samples undergoclockwise P-T-t paths:
Metamorphic Field
Gradient
Thus, metamorphism of rocks needs to be viewed as a dynamic process in which pressure and
temperature conditions change. Note that the maximum P on a given path does not correspond to the
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maximum T. If the three samples were collected in a metamorphic terrane, mineral assemblages
corresponding to the maximum Treached by each sample would define a metamorphic field gradient.
(Typically, near-maximum T conditions are preserved in mineral assemblages of metamorphic rocks
because retrograde reactions are energetically difficult.)
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IV. Nomenclature of Metamorphic Rocks
The best classification of metamorphic rocks is the faciesclassification, in which mineral assemblages
are used to define ranges of P-T conditions. We will discuss metamorphic facies later. However, names
are also given to metamorphic rocks that may be indicative of their morphology, mineralogy, or bulk
chemical composition.
1. Structural (morphological) classification
Hornfels - non-schistose, fine-grained rock with 'granoblastic' fabric (mosaic of small mineral grains).
May have porphyroblasts. Hornfelsic texture is usually produced by contact metamorphism where there
is no deviatoric stress.
Slate - Fine-grained rock with perfect foliation usually defined by sericite and chlorite.
Phyllite - Fine-grained foliated rock but coarser-grained than slate. Muscovite imparts sheen to it.
Schist Medium to coarse grained foliated and commonly lineated rock in which most individual
mineral grains can be recognized without a hand-lens.
(Slate, phyllite, schist most commonly develop in pelitic rocks and tend to indicate a progression in
grade.)
Gneiss - Medium to coarse-grained rock that is discontinuously banded, with banding generallyseparating feldspar/quartz from biotite/hbld/px. The production of some gneisses may also involve
partial melting.
2. Bulk chemical composition (indicates the protolith of a metamorphic rock)
Pelitic - derived from aluminous sediments (shales). Micas are abundant as are other aluminous
minerals, including the aluminosilicates, pyralspite garnets, staurolite, and cordierite.
Quartzo-feldspathic - derived from sandstones, tuffs, granites. The principal minerals are quartz andfeldspars.
Calcareous - derived from calcareous rocks. The principal minerals are either calcite or dolomite.
Calc-silicate- derived from mixed calcareous and pelitic protoliths. Calcite, dolomite, muscovite,
chlorite, and biotite are common at low grades, whereas diopside, tremolite, grossular garnet,
wollastonite, and vesuvianite are common at high grades.
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Basic - Derived from mafic igneous rocks. Typical minerals are chlorite, hornblende, plagioclase,
epidote, pyroxene.
Magnesian - derived from ultramafic rocks (peridotites). Serpentine, talc, magnesite, and brucite
common.
The metamorphism of the last two groups is essentially retrograde.
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3. Traditional names indicating the dominant mineralogy
Marble - non-foliated or weakly foliated rock composed dominantly of calcite or less commonly
dolomite.
(Meta-)Quartzite - recrystallized sedimentary quartzite (sandstone).
Amphibolite - composed essentially of hornblende and plagioclase. It is often foliated and lineated.
Eclogite - Dominantly omphacite clinopyroxene and garnet (kyanite).
omphacite - (Ca,Na)(Mg,Fe2+,Fe3+,Al)Si2O6
garnet - pyrope-almandine solid solution.
4. Modifiers and prefixes
Modifiers may be placed in front of the above names, e.g. :
tremolite marble
hornblende gneiss
garnet-biotite schist
staurolite-andalusite schist
Common prefixes:
Meta - Used to describe an originally igneous or sedimentary rock that was metamorphosed to indicate
the protolith. E.g. meta-basalt, meta-graywacke, meta-gabbro, meta-arkose
Ortho - Indicates that the metamorphic rock was originally igneous. E.g. orthogneiss, orthoamphibolite
Para - Indicates that the metamorphic rocks was originally sedimentary, e.g. paragneiss,
paraamphibolite.
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V. Concept of Metamorphic Facies
Terms such as low grade, medium grade, or high grade are only useful for comparing the metamorphic
grade in a given area. These terms are worthless when comparing different terranes that may follow
different metamorphic field gradients. For example, a blueschist series rock may be metamorphosed at
high pressures but fairly low temperature, whereas a contact-metamorphic rock may be metamorphosed
at high temperature but low pressure. Much more useful is the concept ofmetamorphic facies, where
each facies defines a certain range of P-Tconditions. The facies concept was proposed by Turner in
1968:
"A metamorphic facies is a set of metamorphic mineral assemblages, ... , such that there is a constant
and therefore predictable relationship between mineral composition and chemical composition.
Eclogite
Blueschist
PrehnitePumpelyite
Zeolite
Greenschist
Amphibolite
Granulite
Albite-epidotehornfels
Hornblendehornfels
Pyroxenehornfels Sanidine
10
12
8
6
4
2
0100 200 300 400 500 600 700 800 900
temperature(C)
Explanation of the definition:
Each facies defines a restricted set of P-T conditions.
To belong to the same facies, rocks of the same chemical composition must have the same
mineral assemblage. However, rocks of different composition may have a different assemblage
at the same facies. For example, in the greenschist facies:
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basic composition: plagioclase, chlorite, actinolite, epidote
pelitic composition: quartz, chlorite, muscovite, garnet, biotite.
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Facies boundaries may not be shown by all compositions:
epidote + tremolite
pyrophyllite +
muscovite +coriderite+ qtz
andalusite +
muscovite +cordierite+ qtz
albite-epidote
hornfles
hornblende
hornfles
pyroxene
hornfles
pelitic
basic
calcareous
garnet + tremolite +
plagioclase
garnet + diopside +plagioclase
calcite calcite calcite
sillimanite +
cordierite + Kspar